Fingertip medical vibratory device

ABSTRACT

An apparatus comprising a vibrating finger device useful in a medical setting includes a device body configured to fit on a finger of a wearer, a vibrating unit, a touch sensitive sensor, and a control module including a computerized processor. The control module includes programming configured to monitor an activation input to the device, determine the monitored activation input to indicate a threshold desired vibration activation input, and activate a vibration cycle within the vibrating unit based upon the determination.

CROSS-REFERENCE TO RELATED APPLICATIONS

This disclosure is a continuation of U.S. patent application Ser. No.16/429,849 filed on Jun. 3, 2019 and claims priority to U.S. ProvisionalPatent Application No. 62/679,266 filed on Jun. 1, 2018, which is herebyincorporated by reference.

TECHNICAL FIELD

This disclosure is related to a finger device useful to provide avibratory input to skin brought in proximity to the device, inparticular, to a device configured to be worn under medical gloves.

BACKGROUND

The statements in this section merely provide background informationrelated to the present disclosure. Accordingly, such statements are notintended to constitute an admission of prior art.

Doctors and other medical personnel sometimes seek to lessen the painassociated with injections and another needle pricks that patients mustendure. One method to lessen this pain is through tactile stimulation orby pressing a finger into the area that is about to be pricked and movethe finger vigorously for a few seconds. This stimulation by thedoctor's finger, under a theory of pain known as the gate controltheory, causes the nerves in the area to send intense touch signals tothe brain. This sudden touch stimulation partially overloads the brain'sability read nerve inputs from that area of the skin, such that when ahypodermic needle is subsequently injected in that skin, the sensationrelated to the needle prick that is input by the brain is less intensethan it would be without the prior stimulation.

Finger vibratory devices are known, in particular, related toadult/intimacy products. Such products are put upon a fingertip, andwhen pressure is applied to the fingertip, a circuit is activatedcreating a vibration in the fingertip device. While such a device couldbe useful for tactile stimulation, a device such as that would beunsanitary or unsterile for use in a medical environment. Testing hasshown that such devices, when a medical glove is put on over the device,tends to stay on due to the constant pressure that the glove puts on thefinger and device or tends to turn on every time that the doctor's handtouches any object.

SUMMARY

An apparatus including a vibrating finger device useful in a medicalsetting is provided and includes a device body configured to fit on afinger of a wearer, a vibrating unit, a touch sensitive sensor, and acontrol module including a computerized processor. The control moduleincludes programming configured to monitor an activation input to thedevice, determine the monitored activation input to indicate a thresholddesired vibration activation input, and activate a vibration cyclewithin the vibrating unit based upon the determination.

According to one or more embodiments, the control module including thecomputerized processor includes a circuit board.

According to one or more embodiments, the device is configured to beworn under a medical glove.

According to one or more embodiments, the touch sensitive sensor islocated at a tip of the device body, and the vibrating unit is locatedat the tip of the device body.

According to one or more embodiments, the touch sensitive sensor islocated on a back side of the device body, the vibrating unit is locatedon the back side of the device body, the control module including thecomputerized processor includes a circuit board, and the circuit boardis located on the back side of the device body.

According to one or more embodiments, the programming configured toactivate the vibration cycle includes programming configured to controlthe vibration cycle at a constant vibration magnitude.

According to one or more embodiments, the programming configured toactivate the vibration cycle includes programming configured to controlthe vibration cycle at a constant vibration magnitude.

According to one or more embodiments, the programming configured toactivate the vibration cycle includes programming configured to controlthe vibration cycle with a vibration magnitude escalating over time.

According to one or more embodiments, the programming configured toactivate the vibration cycle includes programming configured to controlthe vibration cycle with a vibration magnitude oscillating over time.

According to one or more embodiments, the programming configured tomonitor the activation input includes programming configured to monitorthe touch sensitive sensor.

According to one or more embodiments, the control module furtherincludes programming configured to control parameters of the vibrationcycle based upon monitoring the touch sensitive sensor.

According to one or more embodiments, the control module furtherincludes programming configured to select one of a plurality ofvibration programs based upon monitoring the touch sensitive sensor.

According to one or more embodiments, the apparatus further includes anon/off switch, and the programming configured to monitor the activationinput includes programming configured to monitor the on/off switch.According to one or more embodiments, the control module furtherincludes programming configured to monitor the touch sensitive sensor asa secondary input. According to one or more embodiments, the programmingconfigured to activate the vibration cycle includes programmingconfigured to authorize the vibration cycle based upon the monitoredactivation input exceeding the threshold desired vibration activationinput, and programming configured to trigger the vibration cycle basedupon the secondary input. According to one or more embodiments, thecontrol module further includes programming configured to control one ofa duration and intensity of the vibration cycle based upon the secondaryinput. According to one or more embodiments, the control module furtherincludes programming configured to select one of a plurality ofvibration programs based upon the secondary input.

An apparatus including a vibrating finger device useful in a medicalsetting is provided and includes a device body configured to fit on afinger of a wearer, a vibrating unit, a touch sensitive sensor, and acircuit board. The circuit board includes programming configured tomonitor the touch sensitive sensor, determine the monitored touchsensitive sensor to indicate a threshold desired vibration activationinput, and activate a vibration cycle within the vibrating unit basedupon the determination. The device is configured to be worn under amedical glove.

BRIEF DESCRIPTION OF THE DRAWINGS

One or more embodiments will now be described, by way of example, withreference to the accompanying drawings, in which:

FIG. 1 illustrates an exemplary vibratory fingertip device in sidesectional view, in accordance with the present disclosure;

FIG. 2 illustrates the vibratory fingertip device of FIG. 1 from a topview, in accordance with the present disclosure;

FIG. 3 illustrates the vibratory fingertip device of FIG. 1 from abottom view, in accordance with the present disclosure;

FIG. 4 illustrates an alternative exemplary vibratory fingertip devicein side sectional view, in accordance with the present disclosure;

FIG. 5 illustrates the vibratory fingertip device of FIG. 4 situatedupon a finger of a user with a medical glove worn over the device, inaccordance with the present disclosure;

FIGS. 6-8 illustrate exemplary vibration profiles that can be used tocontrol either or both the vibration magnitude and frequency of thevibration provided by the disclosed devices, in accordance with thepresent disclosure;

FIGS. 9 and 10 illustrate exemplary force input filtration and selectiveactivation techniques, in accordance with the present disclosure;

FIG. 11 illustrates an alternative exemplary vibratory fingertip devicein top view, in accordance with the present disclosure; and

FIG. 12 is a flowchart illustrating an exemplary process to activate oneof a plurality of vibration cycles, in accordance with the presentdisclosure.

DETAILED DESCRIPTION

A vibratory fingertip device is provided for use in medicalenvironments, wherein a computerized processor within the devicemonitors inputs to the device, determines a threshold desired vibrationactivation input, and activates a vibration cycle based upon thedetermination. Devices in the art that simply vibrate when a touchsensitive sensor is activated are not useful in a medical environmentbecause a doctor cannot tolerate a device that unintentionally vibratesevery time an incidental contact is made. The disclosed device is usefulunder known medical gloves, and the device includes hardware and/orsoftware to prevent accidental or incidental activation of the vibrationfeature outside of the desired tactile stimulation function.

Referring now to the drawings, wherein the showings are for the purposeof illustrating certain exemplary embodiments only and not for thepurpose of limiting the same, FIG. 1 illustrates an exemplary vibratoryfingertip device in side sectional view. Any number of physicalarrangements or alternative equivalent components for the illustrateddevice are envisioned, and the disclosure is not intended to be limitedto the exemplary embodiment of FIG. 1. FIG. 1 illustrates fingertipdevice 10 including polymerized, flexible device body 20 includingfingertip shaped cavity 22. Tip 24 includes a touch sensitive sensor 50may be configured to measure pressure applied by the finger of thewearer upon proximate surfaces such as the skin of a patient. Tip 24also includes vibration unit 40 which can include a small motor andoff-center weight, such that when the motor spins, the off-center weightcauses the device to vibrate. Touch sensitive sensor 50 and vibrationunit 40 can be fully encapsulated within surface 23 of body 20. Acomputerized processor is provided within exemplary circuit board 30.Vibration unit 40 can be electronically connected though wire bundle 36to circuit board 30 which includes coded programming and/orfunctionality to control vibration of vibration unit 40 based uponmonitored force inputs from touch sensitive sensor 50. Circuit board 30can be connected to exemplary round wrist-watch-style battery 60 throughelectrodes 32 and 34. Electrode 34 includes spring-activated conductivebracket 28 which aids in holding battery 60 in place. Body 20 includesflap 29 configured to cover battery 60 and further includes annular ring26 configured to prevent the bottom of body 20 from rolling up upon thefinger of the user. Surface 23 includes flat end 27 configured to beplaced squarely next to the skin of the user such that accurate forcereadings can be measured by touch sensitive sensor 50.

Touch sensitive sensor 50 can act as an activation input or an inputused to determine whether a vibration cycle should be activated, withthe device monitoring pressure applied to the touch sensitive sensor 50and determining a desire to activate a vibration cycle based upon theactivation input. In determining whether inputs to the device throughthe activation input do indicate the desire to activate a vibrationcycle, the inputs to the device are compared to a programmed thresholdor a threshold desired vibration activation input, and if the inputsexceed the threshold desired vibration activation input, then thevibration cycle can be activated. Other inputs in place of a touchsensitive sensor can be used as an activation input, for example,including an on/off switch. In such an embodiment, a touch sensitivesensor can be used as a secondary input, for example, providing controlparameters for the vibration cycle to be performed or triggering thealready activated vibration cycle.

Touch sensitive sensor 50 can include any of a wide variety of touchsensors in the art or sensor capable of measuring pressure applied by ortouching contact of a finger of a wearer through the disclosed vibratoryfingertip device. In one embodiment, touch sensitive sensor 50 caninclude a wire resistive sensor, wherein electrical resistance of acircuit can be changed or a previously open circuit can be closed basedupon force applied to the sensor. In another embodiment, touch sensitivesensor 50 can include an infrared sensitive sensor.

A computerized processor is provided within exemplary circuit board 30.Circuit board 30 includes hardware in the art configured to performcomputerized functionality. In the present device, circuit board 30utilizes programmed code to monitor inputs to the device, either to atouch sensitive sensor and/or an on/off switch to determine when adoctor or user intend the device initiate a vibration cycle. Thecomputerized processor within the device illustrated in FIG. 1 monitorsinputs the device, in particular, inputs to the touch sensitive sensor,determines a threshold desired vibration activation input, and activatesa vibration cycle based upon the determination.

FIG. 2 illustrates the vibratory fingertip device of FIG. 1 from a topview. Device 10 is illustrated including body 20 including annular ring26, circuit board 30, battery 60, spring-activated conductive bracket28, flap 29, and surface 23.

FIG. 3 illustrates the vibratory fingertip device of FIG. 1 from abottom view. Device 10 is illustrated including body 20 includingannular ring 26, surface 23, vibration unit 40, and touch sensitivesensor 50.

Body 20 of the device may be constructed of various differentpolymerized materials, the material may have various differentdurometers, and the device may have different dimensions from theillustrated examples.

FIG. 4 illustrates an alternative exemplary vibratory fingertip devicein side sectional view. Device 110 is illustrated including flexibledevice body 120 including a fingertip shaped cavity with tip 124. Avibration unit 140, circuit board 130, battery 160, and activationbutton 150 are illustrated on a back or upper side of the device, withno vibration features located on a tip of device 110. Activation button150 can be described as a touch sensitive sensor similar to the touchsensitive sensor of FIG. 1. End 126 of body 120 is illustrated withoutan annular ring in order to facilitate easy use, easy taking off andputting on of medical gloves without the device hanging up on therubberized surface of the glove. Device 110 permits a doctor to use herhand normally, with no electronic devices between the fingertip and thepatient's skin. When the doctor wants to activate the tactilestimulation feature, the doctor can hit button 150, bend her finger, andpress vibration device 140 against the skin of the patient. In oneexemplary use, the doctor can press button 150, and the vibration devicecan be activated 3 seconds later to vibrate for 10 subsequent seconds.

The computerized processor within the device illustrated in FIG. 4,embodied as circuit board 130, monitors inputs to the device, inparticular, inputs to the touch sensitive sensor, determines a thresholddesired vibration activation input, and activates a vibration cyclebased upon the determination.

FIG. 5 illustrates the vibratory fingertip device of FIG. 4 situatedupon a finger of a user with a medical glove worn over the device. Hand200 is illustrated with device 10 installed to the middle finger of theuser. Glove 210 is illustrated worn over device 10.

FIGS. 6-8 illustrate exemplary vibration profiles that can be used tocontrol either or both the vibration magnitude and frequency of thevibration provided by the disclosed devices. FIG. 6 illustratesexemplary vibration magnitude on a vertical axis and time on ahorizontal axis. A constant vibration magnitude is shown for some timeperiod. FIG. 7 illustrates exemplary vibration magnitude on a verticalaxis and time on a horizontal axis. FIG. 7 illustrates the vibrationmagnitude escalating over time. An increasing magnitude, increasing insteps, is illustrated, over a time period. In other examples, themagnitude can increase gradually. FIG. 8 illustrates exemplary vibrationmagnitude on a vertical axis and time on a horizontal axis. Themagnitude of the vibration changes or oscillates over time in anexemplary sinusoidal form, with the magnitude oscillating up and downover the illustrated time period. The oscillation could in otherexamples include step-form oscillations. FIGS. 6-8 are exemplary, andthe disclosure is not intended to be limited to the particular examplesprovided.

The computerized processor of the disclosed device can monitor inputs tothe device and determine whether the monitored inputs indicate athreshold desired vibration activation input. An on-off switch canprovide an input to the device useful to determine whether the monitoredinputs indicate a threshold desired vibration activation input. Inanother embodiment, inputs to the touch sensitive sensor of the devicecan be useful to determine whether the monitored inputs indicate athreshold desired vibration activation input. For example, pressureapplied to the touch sensitive sensor may be required to be appliedconstantly for a set time period or duration, for example, 3, 4, or 5seconds in order to that constant pressure to indicate a thresholddesired vibration activation input. In another example, a rapid repeatedinputs to the touch sensitive sensor, for example, three tapping inputswithin one second or one and a half seconds, may be required in order tothat constant pressure to indicate a threshold desired vibrationactivation input. In another example, a constant pressure for a requiredduration followed by a tapping input or a number of tapping inputs maybe required in order for the inputs to indicate a threshold desiredvibration activation input.

In one exemplary embodiment, the computerized process may be equipped torun two or more different vibration cycles, for example, of differentduration or intensity, and inputs to the touch sensitive sensor mayenable activation of the different alternative vibration cycles basedupon the inputs to the touch sensitive sensor. For example, an input ofa required duration may be required to “arm” the device, and then anumber of tapping inputs within an activation duration may be requiredto select a vibration program. For example, a computerized processorcould include code to monitor inputs from a touch sensitive sensor,“arm” the system based upon receiving a constant pressure input of atleast two seconds, and then activate a first vibration cycle if onetapping input is monitored within three seconds of arming, alternativelyactivate a second vibration cycle if two tapping inputs are monitoredwithin three seconds of arming, and alternatively activate a thirdvibration cycle if three tapping inputs are monitored within threeseconds of arming. If no tapping inputs are monitored within the threesecond activation duration, then the system “disarms.”

A number of different processes for monitoring a touch sensitive sensorand determining that the inputs indicate a threshold desired vibrationactivation input are envisioned, and the disclosure is not intended tobe limited to the examples provided herein.

FIGS. 9 and 10 illustrate exemplary force input filtration and selectiveactivation techniques useful to determine that the inputs indicate athreshold desired vibration activation input. Accidental or incidentalactivation of the vibration feature of the disclosed devices can beadverse to use in a medical environment. Patients can be unnecessarilystartled by an unintended vibration, and a doctor can be distracted byan unintended vibration. FIG. 9 illustrates a force measured by afingertip sensor on the device on a vertical axis and time on ahorizontal axis. FIG. 9 can illustrate a computerized processorprogrammed to look for a constant input of at least a minimum durationto activate the device. Peak 301 illustrates a significant input offorce applied to the sensor, however this input of force is not ofsufficient duration to activate a vibration cycle. Peaks 302 illustratesmall, intermittent force inputs to the sensor which can be consistentwith normal use of the user's hand. Peak 303 shows a threshold forceapplied substantially consistently through a time period in excess ofthe minimum duration to activate the device. The disclosed devices canbe programmed to activate only when the doctor presses the deviceagainst skin of a patient for a set duration, for example, for fiveseconds. Star 304 indicates a time that a vibration event can beinitiated based upon the input meeting the criteria of a desiredvibration event. FIG. 10 illustrates a force measured by a fingertipsensor on the device on a vertical axis and time on a horizontal axis.The plot of force starts at zero, for example, with the doctoractivating the device before a glove is placed over the device. FIG. 10can illustrate a computerized processor programmed to look for athreshold plurality of tapping inputs within a duration or period oftime. Peak 311 illustrates a sharp peak of force applied to the sensorwhich can be consistent with placing a glove on the hand of the user.Even though peak 311 is substantial in magnitude, indicating that alarge force was applied to the touch sensitive sensor, peak 311 does notmeet the programmed criteria of the computerized processor of FIG. 10.Peaks 312 illustrate small, intermittent force inputs to the sensorwhich can be consistent with normal use of the user's hand, but peaks312 do not meet the programmed criteria of the computerized processor ofFIG. 10. Peaks 313 illustrate three sequential force inputs or tappinginputs which can be used to indicate the desire of the doctor that avibration event should occur. Star 314 indicates a time that a vibrationevent can be initiated based upon the input meeting the criteria of adesired vibration event. FIGS. 9 and 10 are exemplary, and thedisclosure is not intended to be limited to the particular examplesprovided.

Embodiments of the disclosure are described as being useful for useunder medical gloves. Such use is advantageous because the medical gloveprovides a seal against contamination or intrusion of bacteria or otherorganisms that could be found in a medical treatment setting. However,embodiments of the disclosed device can be used without medical gloves.For example, the embodiment of FIG. 4 is sealed, with all electronicelements being encased in the rubberized or polymer material of thedevice body. Similarly, the device of FIG. 1 can include a seal oradhesive sealing the battery and other internal components such that theinternal electronic mechanisms were entirely encased. In such a casewhere the device is entirely encased within a rubberized or polymermaterial, it can be appreciated that such a device could be used uponthe hand of a person with hand sanitizer or other treatment beingavailable to sanitize the device and keep it in an acceptable state foruse in a medical setting.

FIG. 11 illustrates an alternative exemplary vibratory fingertip devicein top view. The device of FIG. 11 is similar to the device of FIG. 1,except that on/off switch 532 is attached or electronically connected tocircuit board 530. Device 500 is illustrated including body 520including annular ring 526, circuit board 530, battery 560,spring-activated conductive bracket 528, and surface 523. Surface 523covers a touch sensitive sensor and a vibration unit in accordance withthe disclosure. In place of a flap covering the electronics of device500, a cover 529 is attached to body 520 around a perimeter illustratedby a dotted line. The attachment of cover 529 can be performed throughheat bonding, adhesive, or any other joining method in the art. Inanother embodiment, cover 529 can be formed integrally with body 520,with the other components being placed within a formation mold as thematerial for body 520 and cover 529 are initially provided.

On/off switch can be exposed through cover 529 or can be covered bycover 529. Cover 529 may soft enough and may be transparent ortranslucent such that the user can see the switch and activate itthrough cover 529.

In the embodiments of FIGS. 1 and 4, the device can monitor anactivation input including monitoring pressure inputs to the touchsensitive sensor to determine appropriate activation of a vibrationcycle. In such embodiments, the touch sensitive device can act as bothan activation input and as a secondary input, for example, permittinglater triggering of the vibration cycle or the user to controlparameters such as duration or intensity of the vibration cycle. Inanother embodiment, the on/off switch of FIG. 11 can be the activationinput for the device. The device can then take a secondary input orcontrol input from the touch sensitive sensor, for example, receiving asecond input, for example, controlling one of a duration or intensity ofthe vibration cycle. In another embodiment, after the activation inputfrom the on/off switch is received, the unit can be primed to activatethe vibration cycle as soon as a pressure input is received through thetouch sensitive sensor. In this example, activation of the vibrationcycle can be said to include two steps, one, the input to the activationinput authorizes the vibration cycle, and, two, the input to thesecondary input triggers the vibration cycle.

It will be appreciated that other similar embodiments of the disclosedinvention can include an activation input without requiring use of atouch-sensitive sensor. For example, an on/off button can be used, wherethe device is programmed to vibrate for fifteen seconds after the on/offbutton is activated. In another example, the device can be programmed toactivate a vibration cycle based upon monitoring a voice input to amicrophone connected to the circuit board. Other activation inputs notrelated to a touch sensitive sensor are envisioned and the disclosure isnot intended to be limited to the examples provided herein.

FIG. 12 is a flowchart illustrating an exemplary process to activate oneof a plurality of vibration cycles. Process 400 starts at step 402. Atstep 404, the device, or particularly a computerized processor of thedevice, monitors input to a touch sensitive sensor of the device. Atstep 406, the computerized processor determines whether the input to thetouch sensitive sensor matches an activation trigger indicating athreshold desired vibration activation input. If no monitored inputmatches the activation trigger, the process returns to step 404. If themonitored input does match the activation trigger, the process advancesto step 408, where the computerized processor determines whether theactivation trigger indicates desired activation of vibration programone, vibration program two, or vibration program three. If theactivation trigger indicates desired activation of vibration programone, the process advances to step 410 where vibration program one isoperated. If the activation trigger indicates desired activation ofvibration program two, the process advances to step 412 where vibrationprogram two is operated. If the activation trigger indicates desiredactivation of vibration program three, the process advances to step 414where vibration program three is operated. At step 416, the processends. Process 400 is exemplary, and the disclosure is not intended to belimited to the exemplary process steps illustrated herein.

In one embodiment, a secondary input can be utilized to select between aplurality of vibration programs.

The disclosure has described certain preferred embodiments andmodifications of those embodiments. Further modifications andalterations may occur to others upon reading and understanding thespecification. Therefore, it is intended that the disclosure not belimited to the particular embodiment(s) disclosed as the best modecontemplated for carrying out this disclosure, but that the disclosurewill include all embodiments falling within the scope of the appendedclaims.

1. An apparatus comprising a vibrating finger device useful in a medicalsetting, comprising: a device body configured to fit on a finger of awearer; a vibrating unit; a touch sensitive sensor; and a control modulecomprising a computerized processor, including programming configuredto: monitor an activation input to the device; determine the monitoredactivation input to indicate a threshold desired vibration activationinput; and activate a vibration cycle within the vibrating unit basedupon the determination.
 2. The apparatus of claim 1, wherein the controlmodule comprising the computerized processor comprises a circuit board.3. The apparatus of claim 1, wherein the device is configured to be wornunder a medical glove.
 4. The apparatus of claim 1, wherein the touchsensitive sensor is located at a tip of the device body; and wherein thevibrating unit is located at the tip of the device body.
 5. Theapparatus of claim 1, wherein the touch sensitive sensor is located on aback side of the device body; wherein the vibrating unit is located onthe back side of the device body; the control module comprising thecomputerized processor comprises a circuit board; and wherein thecircuit board is located on the back side of the device body.
 6. Theapparatus of claim 1, wherein the programming configured to activate thevibration cycle comprises programming configured to control thevibration cycle at a constant vibration magnitude.
 7. The apparatus ofclaim 1, wherein the programming configured to activate the vibrationcycle comprises programming configured to control the vibration cycle ata constant vibration magnitude.
 8. The apparatus of claim 1, wherein theprogramming configured to activate the vibration cycle comprisesprogramming configured to control the vibration cycle with a vibrationmagnitude escalating over time.
 9. The apparatus of claim 1, wherein theprogramming configured to activate the vibration cycle comprisesprogramming configured to control the vibration cycle with a vibrationmagnitude oscillating over time.
 10. The apparatus of claim 1, whereinthe programming configured to monitor the activation input comprisesprogramming configured to monitor the touch sensitive sensor.
 11. Theapparatus of claim 10, wherein the control module further includesprogramming configured to control parameters of the vibration cyclebased upon monitoring the touch sensitive sensor.
 12. The apparatus ofclaim 10, wherein the control module further includes programmingconfigured to select one of a plurality of vibration programs based uponmonitoring the touch sensitive sensor.
 13. The apparatus of claim 1,further comprising an on/off switch; and wherein the programmingconfigured to monitor the activation input comprises programmingconfigured to monitor the on/off switch.
 14. The apparatus of claim 13,wherein the control module further includes programming configured tomonitor the touch sensitive sensor as a secondary input.
 15. Theapparatus of claim 14, wherein the programming configured to activatethe vibration cycle comprises: programming configured to authorize thevibration cycle based upon the monitored activation input exceeding thethreshold desired vibration activation input; and programming configuredto trigger the vibration cycle based upon the secondary input.
 16. Theapparatus of claim 14, wherein the control module further includesprogramming configured to control one of a duration and intensity of thevibration cycle based upon the secondary input.
 17. The apparatus ofclaim 14, wherein the control module further includes programmingconfigured to select one of a plurality of vibration programs based uponthe secondary input.
 18. An apparatus comprising a vibrating fingerdevice useful in a medical setting, comprising: a device body configuredto fit on a finger of a wearer; a vibrating unit; a touch sensitivesensor; and a circuit board, including programming configured to:monitor the touch sensitive sensor; determine the monitored touchsensitive sensor to indicate a threshold desired vibration activationinput; and activate a vibration cycle within the vibrating unit basedupon the determination; wherein the device is configured to be wornunder a medical glove.